Liquid ejection apparatus and control method thereof

ABSTRACT

A simple, low-cost liquid ejection apparatus is provided which can prevent a reverse flow of ink from within the cap into the print head, which would otherwise occur when the interior of the cap is returned to an atmospheric pressure. For this purpose, the ink is sucked out of the nozzle ports of the print head by the recovery unit with the atmospheric vent valve of the subtank open.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a liquid ejection apparatus used in inkjet printing apparatus and the like and also to a method of controllingthe same.

2. Description of the Related Art

A general suction-based recovery operation employed in the ink jetprinting apparatus will be briefly explained.

In executing the suction-based recovery operation, a general ink jetprinting apparatus first causes a cap, which receives sucked-out ink, tocome into contact with that face of an ink jet print head (hereinafteralso referred to simply as a print head) in which nozzle ports for inkejection are formed. Next, a suction pump connected to the cap is drivento produce a negative pressure in the cap to suck the viscous ink fromthe nozzle ports out into the cap. At this time, since the sucked-outink is discarded as waste ink, the sucking of ink in an amount more thannecessary is not desirable. Therefore, a general ink jet printingapparatus, after a predetermined duration of driving the suction pump,opens a release valve on the cap. Alternatively, the cap is parted fromthe nozzle ports to introduce an atmospheric pressure into the cap, thuslimiting the amount of ink being sucked out to the minimum required.

In returning the interior of the cap to the atmospheric pressure, if anabsolute value of the negative pressure in the ink jet print head is toolarge, the ink that has been sucked out into the cap may get back intothe print head. As it is brought back into the print head, the ink maycarry with it foreign matters, such as dirt in the cap, into the printhead, resulting in improper ejections. In an ink jet printing apparatusconstructed to suck out different colors of ink through a common cap, aso-called color mixing may result at time of ink ejection.

Japanese Patent Application Laid-Open No. 2005-144939 discloses atechnique for preventing color mixing, employed in an ink jet printingapparatus that sucks out different colors of ink through a common cap.Japanese Patent Application Laid-Open No. 2005-144939 prevents the colormixing by supplying ink from an ink cartridge to subtanks to lower theabsolute values of the negative pressures in the subtanks or to make thenegative pressures equal for all colors.

However, experiments of the inventors have found that even if thenegative pressures of the subtanks for different colors were set equal,too large an absolute value of the negative pressure in the print headwhen the interior of the cap is returned to an atmospheric pressure canresult in the color mixing.

Generally, only supplying ink from the ink cartridge to the subtankscannot lower the absolute values of negative pressure in the subtanks.To lower the absolute values of negative pressure in the subtanksrequires, as disclosed in Japanese Patent Application Laid-Open No.2005-144939, a negative pressure generation mechanism or the like in thesubtanks, making the apparatus complicated.

SUMMARY OF THE INVENTION

It is therefore an object of this invention to realize a low-cost liquidejection apparatus of simple construction capable of preventing inkwithin a cap from flowing back into the print head when the interior ofthe cap is restored to an atmospheric pressure. It is another object ofthis invention to realize a method of controlling the liquid ejectionapparatus.

According to the present invention, a liquid ejection apparatuscomprising:

a print head to eject a liquid from ejection ports;

a first reservoir means to store the liquid;

a supply means to supply the liquid stored in the first reservoir meansto the print head;

an atmospheric vent installed in the supply means and able tocommunicate with atmosphere; and

a suction means to suck out the liquid from the print head;

wherein, when the liquid is ejected from the print head, the atmosphericvent is brought out of communication with the atmosphere and, when theliquid is sucked out from the print head by the suction means, theatmospheric vent is brought into communication with the atmosphere.

According to the present invention, a method of controlling a liquidejection apparatus, wherein the liquid ejection apparatus has a printhead to eject a liquid from ejection ports, a first reservoir means tostore the liquid, a supply means to supply the liquid stored in thefirst reservoir means to the print head, an atmospheric vent installedin the supply means and able to communicate with atmosphere, and asuction means to suck out the liquid from the print head, the controlmethod comprising the steps of:

ejecting the liquid from the print head with the atmospheric vent keptout of communication with the atmosphere; and

sucking out the liquid from the print head by the suction means with theatmospheric vent brought into communication with the atmosphere.

This invention has made it possible to realize a low-cost liquidejection apparatus of simple construction that can prevent a backflow ofink from within the cap into the print head when the interior of the capis restored to an atmospheric pressure, and also a method of controllingthe liquid ejection apparatus.

Further features of the present invention will become apparent from thefollowing description of exemplary embodiments (with reference to theattached drawings).

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view schematically showing essential partsof the liquid ejection apparatus as a first embodiment; and

FIG. 2 is a cross-sectional view schematically showing essential partsof the liquid ejection apparatus as a second embodiment.

DESCRIPTION OF THE EMBODIMENTS First Embodiment

Now, a first embodiment of this invention will be explained by referringto the accompanying drawing.

FIG. 1 is a cross-sectional view schematically showing essential partsof the liquid ejection apparatus of this embodiment. Although FIG. 1shows a construction for one kind of liquid, a plurality of the similarconstructions may be provided for a corresponding number of differentkinds of liquids. An ink jet print head (also referred to simply as aprint head) 1000 has a nozzle port-formed surface 1001 having liquidejection ports (nozzle ports) for ejecting liquid (ink) formed therein.In each of the nozzle ports there is provided an electrothermalconverter which, when applied an electric signal, generates a bubble inink whose pressure expels an ink droplet from the nozzle ports.

The liquid ejection means is constructed mainly of these electrothermalconverters and nozzles. A main tank (first reservoir means) 1010 hasrubber plugs 1011, 1012 with a slit. When the main tank 1010 is mountedon the liquid ejection apparatus, a supply needle 1021 installed in abuffer chamber 1020 and a supply needle 1031 installed in a secondreservoir means (subtank) 1030 pierce through the rubber plugs 1011,1012. The buffer chamber 1020 is provided with a second atmospheric vent1022. The first reservoir means is constructed mainly of the main tank1010, supply needle 1021 and buffer chamber 1020. The subtank 1030 isprovided with a first atmospheric vent 1032 that can be brought into orout of communication with atmosphere as an atmospheric vent valve 1033is opened and closed.

Provided between the subtank 1030 and the print head 1000 is an inksupply tube 1040 through which ink stored in the subtank 1030 issupplied to the print head 1000. A liquid supply means is constructedmainly of the supply needle 1031, the ink supply tube 1040 and a part ofthe print head 1000. Further, the liquid ejection apparatus has a liquidsuction means constructed mainly of a cap 1050, a suction tube 1051, asuction pump 1052, an atmospheric relief tube 1053 and an atmosphericrelief valve 1054.

Now, in the liquid ejection apparatus of the first embodiment, anexplanation on the liquid suction operation will be given as follows. Anoriginal ejection performance is recovered by removing viscous ink anddirt from inside the nozzles by suction. For this purpose, in suckingout a liquid (ink) from the liquid ejection ports (nozzle ports), thefirst step is to engage the cap 1050 against the nozzle port-formedsurface 1001 of the print head 1000 and then close the atmosphericrelief valve 1054. Next, the atmospheric vent valve 1033 is opened,followed by the suction pump 1052 being driven. With the suction pump1052 operated, the interior of the cap 1050 becomes negative inpressure, drawing the ink out of the nozzle ports of the print head 1000into the cap 1050. The ink thus sucked out is led to a waste ink tanknot shown. Since the ink is sucked out with the atmospheric vent valve1033 open, air enters through the first atmospheric vent 1032.

After the suction pump 1052 has been operated for a predeterminedperiod, the atmospheric relief valve 1054 is opened, communicating theinterior of the cap 1050 to the atmosphere to let the open air flow intothe cap 1050 through the atmospheric relief tube 1053. At this timealthough some negative pressure remains in the interior of the printhead 1000, its absolute value is small compared with that when thesimilar suction operation is done with the atmospheric vent valve 1033closed. This is because a flow resistance in a path from the firstatmospheric vent 1032 to the nozzle ports is smaller than the one fromthe second atmospheric vent 1022 to the nozzle ports. As the operationof the suction pump 1052 increases the absolute value of the negativepressure within the cap 1050, the absolute value of the negativepressure in the print head 1000 also increases. However, the negativepressure in the print head 1000 begins to decrease as the ink issupplied to the print head from the ink supply tube 1040. That is, thesmaller the flow resistance in the path from the first atmospheric vent1032 to the print head 1000, the smaller the absolute value of thenegative pressure inside the print head 1000 will be when theatmospheric relief valve 1054 is opened.

There are two supply needles 1021, 1031 with extremely small diametersin an ink path between the first atmospheric vent 1032 and the secondatmospheric vent 1022. Therefore, the flow resistance in the path fromthe second atmospheric vent 1022 to the nozzle ports is greater thanthat from the first atmospheric vent 1032 to the nozzle ports. If theabsolute value of the negative pressure in the print head 1000 at timeof opening the atmospheric relief valve 1054 is small, it is almostunlikely that the ink that has been sucked out into the cap 1050 mayflow back into the print head 1000. This in turn avoids foreign mattersbeing drawn into the print head 1000 along with the reverse-flowing ink,which results in an extremely low frequency of occurrence of improperejection.

Sucking out ink with the atmospheric vent valve 1033 open, as describedabove, has resulted in almost no ink backflow into the print head 1000,making the frequency of occurrence of improper ejection caused by thetrapping of foreign matters in the print head 1000 extremely low.Although in the above construction the suction pump 1052 has beendescribed to be operated after opening the atmospheric vent valve 1033,the atmospheric vent valve 1033 may be opened at any time while thesuction pump 1052 is operated. This is because even such a constructioncan also make small the absolute value of the negative pressure insidethe print head 1000 following the suction operation.

After the atmospheric relief valve 1054 is open, it is preferred thatthe known operations be performed, such as wiping, preliminary ejectionand a cap evacuating suction for clearing the cap 1050 of sucked-outink.

In the liquid ejection apparatus of this embodiment, if the atmosphericvent valve 1033 is left open, the ink stored in the main tank 1010naturally falls into the subtank 1030 by the action of gravity. This,however, takes time. So, the ink in the main tank 1010 may be forciblymoved into the subtank 1030 by the method described below.

An open-close valve is installed in the ink supply tube 1040. Further, asuction pump is installed in the first atmospheric vent 1032. Then, withthe open-close valve closed, the suction pump is operated to draw airfrom the subtank 1030 to force the ink stored in the main tank 1010 toflow into the subtank 1030. In that case, a detection means to detectthe amount of ink accommodated in the subtank 1030 is installed in thesubtank 1030. According to the measurement by the detection means, thestart and stop of the suction pump may be controlled.

In the liquid ejection apparatus of this embodiment, on the other hand,the ink ejection from the nozzle ports is done with the atmospheric ventvalve 1033 closed. This allows the ink stored in the main tank 1010 tobe supplied to the print head 1000 through the subtank 1030 and the inksupply tube 1040 as the ink is consumed by the print head performing theink ejection. As a result, there is no need to drive the pump toforcibly move the ink from the main tank 1010 to the subtank 1030.

It is noted that the amount of ink ejected from the nozzle ports perunit time during the ink ejection operation is much smaller than theamount of ink sucked out of the nozzle ports per unit time during theink sucking operation. Therefore, even if the flow resistance in thepath from the second atmospheric vent 1022 to the nozzle ports is large,no trouble will result.

The liquid ejection apparatus of this embodiment can be applied to aso-called serial type printing apparatus that performs the printing bymoving the ink jet print head in a direction crossing the print mediumfeeding direction. In that case, the apparatus may preferably beconstructed to have the print head 1000 mounted on a movable carriage,which is supplied ink through the ink supply tube 1040. The liquidejection apparatus of this embodiment can also be applied to a full-linetype ink jet printing apparatus that performs the printing by moving aprint medium in a feed direction with the print head kept in a fixedposition.

Second Embodiment

A second embodiment of this invention will be explained by referring tothe accompanying drawing.

While in the first embodiment, the liquid ejection apparatus constructedto eject only one kind of ink has been taken up as an example for theexplanation of the present invention, the second embodiment will explainan example of the liquid ejection apparatus constructed to ejectdifferent kinds (colors) of ink.

FIG. 2 is a cross-sectional view schematically showing essential partsof the liquid ejection apparatus of this embodiment. Those parts in thisembodiment that are identical with the corresponding parts in the firstembodiment are assigned like reference numbers. The liquid ejectionapparatus of this embodiment is constructed to eject four colors—cyan,magenta, yellow and black—and has four systems of the main tank, the inksupply tube and others, one for each of the four colors. The foursystems have entirely the same constructions, so only one system isshown in FIG. 2.

In FIG. 2, an ink jet print head (also referred to simply as a printhead) 2000 has a plurality of nozzle ports to eject four colors of ink.In each of the nozzle ports there is provided an electrothermalconverter.

A main tank 2010 for each color is removably mounted on the liquidejection apparatus and stores ink in a flexible ink bag 2014accommodated in a housing 2013. The ink bag 2014 for each color isprovided with a rubber plug 2011 with a slit. When the main tank 2010 ismounted on the liquid ejection device, a supply needle 2041 connected tothe end of a first ink supply tube 2040 pierces through the rubber plug2011.

The housing 2013 for each color has an O-ring 2015, through which apressure tube 2061 for that color pierces when the main tank 2010 ismounted on the liquid ejection apparatus. The pressure tube 2061 foreach color has mounted thereon a tube-pump type pressure pump 2060 witha pressure tube pressing roller of the corresponding color. An end ofthe pressure tube 2061, which is opposite the end piercing the O-ring2015, communicates with atmosphere.

Further, the first ink supply tube 2040 for each color is connected atits end, opposite the one connected with the supply needle 2041, to asubtank 2030 of the corresponding color. Between the subtank 2030 foreach color and the print head 2000 is installed a second ink supply tube2042 of the corresponding color.

The second ink supply tube 2042 has a supply valve 2043. The subtank2030 for each color is provided with a first atmospheric vent 2032having an atmospheric vent valve 2033. Further, the subtank 2030 is alsoprovided with two sensor pins 2034, 2035 for detecting the amount of inkin the subtank 2030. The presence or absence of electric conductionbetween the two sensor pins 2034, 2035 reveals whether the ink level inthe subtank 2030 for each color is above or below the lower end of thesensor pin 2034.

A cap 1050 is intended to cap all the nozzle ports in the print head2000 that are designed to eject four colors of ink.

An ink suction operation in the liquid ejection apparatus of thisembodiment will be explained as follows. A first step in drawing inkfrom the nozzle ports by suction is to open the supply valve 2043. Next,the cap 1050 is engaged with the nozzle port-formed surface 1001 of theprint head 2000 and in this state the atmospheric vent valve 2033 foreach color is opened. Then, the suction pump 1052 is started to evacuatethe interior of the cap 1050, bringing the pressure in the cap to anegative to draw ink from a plurality of nozzle ports out into the capby suction.

After the suction pump 1052 has been operated for a predeterminedduration, the cap 1050 is parted from the nozzle port-formed surface1001. At this time, although some negative pressure remains in the printhead 2000, as in the case of the first embodiment, the absolute value ofthe negative pressure is substantially smaller than when the similarsuction operation is executed with the atmospheric vent valve 2033closed. This is because the flow resistance in the path from the firstatmospheric vent 2032 for each color to the nozzle ports of thecorresponding color is smaller than that from the main tank 2010 foreach color to the nozzle ports of the corresponding color.

The first ink supply tube 2040 connecting the main tank 2010 and thesubtank 2030 for each color is long and the supply needle 2041 attachedto the end of the first ink supply tube 2090 is small in diameter. Ifthe suction operation is to be performed with the atmospheric vent valve2033 closed, the pressure tube pressing roller of the pressure pump 2060for each color is deactivated. That is, the suction is done bycommunicating the space between the housing 2013 of the main tank 2010and the ink bag 2014 for each color to the atmosphere. This means thatthe resistance the ink bag 2019 exhibits as it is contracted adds to theflow resistance. Therefore, the flow resistance of a path from the maintank 2010 for each color to the nozzle ports of the corresponding colorbecomes large compared with the flow resistance of a path from the firstatmospheric vent 2032 for each color to the nozzle ports of thecorresponding color.

As described above, by performing the suction operation with theatmospheric vent valve 2033 open, the backflow of ink into the printhead 2000 can be prevented almost entirely, eliminating the colormixing. Although in the above construction the suction pump 1052 hasbeen described to be operated after opening the atmospheric vent valve2033, it is possible to open the atmospheric vent valve 2033 while thesuction pump 1052 is in operation. This is because even such aconstruction can also make small the absolute value of the negativepressure inside the print head 2000 following the suction operation.

After the cap 1050 is parted from the nozzle port-formed surface 1001,it is preferred that the known operations be performed, such as wiping,preliminary ejection and a cap evacuating suction for clearing the cap1050 of sucked-out ink. The wiping and the preliminary ejection using asmall volume of ink have proved to be effective in preventing theso-called color mixing. The sucked-out ink is led through the suctiontube 1051 into a waste ink tank not shown.

Since the ink suction operation is done with the atmospheric vent valve2033 open, air enters through the first atmospheric vent 2032 for eachcolor. In the liquid ejection apparatus of this embodiment, the inkstored in the main tank 2010 may be moved into the subtank 2030 afterthe ink has been drawn out of the nozzle ports by suction. As a firststep, a check is made as to whether the sensor pins 2034, 2035 in thesubtank 2030 for each color are electrically conducting. If the sensorpins 2034, 2035 are found not conducting for a particular color, thismeans that the amount of ink of that color in the subtank 2030 isrunning low.

The following operation is performed only on the system of a color forwhich the amount of ink is found to be at a low level. First, the supplyvalve 2043 is closed. Next, the pressure tube pressing roller of thepressure pump 2060 is activated and then the atmospheric vent valve 2033is opened. Then, the pressure pump 2060 is operated to move the ink fromthe main tank 2010 to the subtank 2030. When the sensor pins 2034, 2035in the subtank 2030 become electrically conductive, the pressure pump2060 is stopped. This is followed by the closing of the atmospheric ventvalve 2033, the deactivation of the pressure tube pressing roller of thepressure pump 2060 and the opening of the supply valve 2043.

When the liquid ejection apparatus of this embodiment ejects ink fromits nozzle ports, the pressure tube pressing roller of the pressure pump2060 is deactivated for all colors. That is, the ink ejection operationis done with the space between the housing 2013 and the ink bag 2014 foreach color communicated to the atmosphere and with the atmospheric ventvalve 2033 for each color closed.

This allows the ink stored in the main tank 2010 of each color to besupplied to the print head 2000 through the first ink supply tube 2040and subtank 2030 of the corresponding color as the ink is consumed bythe print head performing the ink ejection. This obviates the need todrive the pump for the forced delivery of ink from the main tank 2010 tothe subtank 2030.

It is noted that the amount of ink ejected from the nozzle ports perunit time during the ink ejection operation is much smaller than theamount of ink sucked out of the nozzle ports per unit time during theink sucking operation. This means that even if the flow resistance inthe path from the main tank 2010 to the nozzle ports is large, notrouble will result.

While the liquid ejection apparatus of the first and second embodimenthave been described to have electrothermal converters installed insidethe nozzle ports of the print head, this invention is not limited tosuch a construction and may use other devices such as piezoelectricdevices.

While the present invention has been described with reference toexemplary embodiments, it is to be understood that the invention is notlimited to the disclosed exemplary embodiments. The scope of thefollowing claims is to be accorded the broadest interpretation so as toencompass all such modifications and equivalent structures andfunctions.

This application claims the benefit of Japanese Patent Application No.2009-056630, filed Mar. 10, 2009 which is hereby incorporated byreference herein in its entirety.

1. A liquid ejection apparatus comprising: a print head to eject aliquid from ejection ports; a first reservoir means to store the liquid;a supply means to supply the liquid stored in the first reservoir meansto the print head; an atmospheric vent installed in the supply means andable to communicate with atmosphere; and a suction means to suck out theliquid from the print head; wherein, when the liquid is ejected from theprint head, the atmospheric vent is brought out of communication withthe atmosphere and, when the liquid is sucked out from the print head bythe suction means, the atmospheric vent is brought into communicationwith the atmosphere.
 2. A liquid ejection apparatus according to claim1, wherein the liquid is a plurality of different kinds of liquid;wherein a set of the print head and the first reservoir means isprovided for each of the plurality of liquids.
 3. A liquid ejectionapparatus according to claim 1, wherein the atmospheric vent isinstalled in a subtank between the first reservoir means and the printhead; wherein, after the liquid has been sucked out of the print head bythe suction means, the liquid stored in the first reservoir means ismoved to the subtank.
 4. A method of controlling a liquid ejectionapparatus, wherein the liquid ejection apparatus has a print head toeject a liquid from ejection ports, a first reservoir means to store theliquid, a supply means to supply the liquid stored in the firstreservoir means to the print head, an atmospheric vent installed in thesupply means and able to communicate with atmosphere, and a suctionmeans to suck out the liquid from the print head, the control methodcomprising the steps of: ejecting the liquid from the print head withthe atmospheric vent kept out of communication with the atmosphere; andsucking out the liquid from the print head by the suction means with theatmospheric vent brought into communication with the atmosphere.
 5. Acontrol method according to claim 4, wherein the liquid is a pluralityof different kinds of liquid; wherein a set of the print head and thefirst reservoir means is provided for each of the plurality of liquids.6. A control method according to claim 4, wherein the atmospheric ventis installed in a subtank between the first reservoir means and theprint head; wherein, after the liquid has been sucked out of the printhead by the suction means, the liquid stored in the first reservoirmeans is moved to the subtank.